RU2605755C2 - Method of fitting floating boom under ice of flowing water reservoir to collect oil products - Google Patents

Abstract

FIELD: technological processes.

SUBSTANCE: invention relates to techniques for cleaning water surface of flowing water reservoirs covered with ice from oil products. Method of fitting floating boom under ice of flowing water reservoir to collect oil products comprises cutting into ice of water reservoir slots and coastal lanes, installation in one coastal lane of a rope-filler with floating boom and cable tension at an angle to dynamic water flow axis. Slots in ice are made in form of cylindrical holes for whole thickness of ice and are located on one line with constant interval, for example 3 m. Line of arrangement of holes is parallel to line of cable tension-filler of floating boom. From one coastal lane of water reservoir is brought under ice to first hole a pole with a mounting cable attached thereto, by directing it to second hole, in which is pole is turned by 180°. Opposite end of pole is directed to third hole, and from one hole to other until reaching pole with mounting cable of opposite coastal lane. Mounting cable is then disconnected from pole, mounting cable is attached to rope-filler with the floating boom and then drawn under ice in direction of lane on opposite side of water reservoir. Further, floating boom is drawn using mounting cable and fixed.

EFFECT: invention allows quick and effective localisation of oil on river water body under ice conditions.

1 cl, 3 dwg

Description

The invention relates to technologies for cleaning the water surface of flowing reservoirs covered with ice from oil products.

A known method of collecting oil from under ice cover using a device according to the copyright certificate of the Russian Federation No. 1765292, class. Ε02B 15/04. Oil is collected by localizing the oil slick using an under-ice boom, which is placed under the ice through the ice hole using an electromagnet, then the oil slick is pulled to the oil receiver by towing the boom by means of a winch and the oil is pumped through the hose using a pump.

A known method of collecting oil from under the ice cover of a flowing reservoir according to the patent of the Russian Federation No. 2107127, class. В02B 15/04, including the localization of the oil polluting spot by making an ice hole and placing a floating boom under the ice cover with the formation of a closed triangular contour into which hot air or gas is injected, and oil is collected in the lower corner of the triangular contour.

The disadvantage of these methods is the relatively low efficiency in flowing reservoirs due to the ablation of part of the oil by the flow beyond the areas marked for cleaning, the boundaries of which are limited by the fixed location of the most important working bodies of devices and ice holes, and the transfer of these boundaries is difficult due to the low mobility of the devices used. In addition, the methods are unsafe due to the need to constantly work on the surface of the ice far from the coast, and special devices for their implementation, such as electromagnets, are also required.

There is also known a method of collecting oil from under the ice cover of a flowing reservoir according to the patent of the Russian Federation No. 2176701, class. Ε02В 15/04, which provides for the opening of the ice cover so that the ice edge forms an acute angle with the course of the river, and the oil accumulated in the coastal zone is sent to fillers prepared in advance on the shore.

This method is also not effective enough, because under freezing conditions at negative air temperature, the water in the slot begins to freeze, supercooled oil, floating up, intensifies the freezing of water and mixes with ice in the slot. As a result, there is no movement of oil (a mixture of oil and ice) to the coastal zone, and oil that has not surfaced continues to move under the ice. In addition, when using the method on large rivers, when opening the ice cover over the entire width of the reservoir, considerable time and effort are required to clear the ice slots after opening it using any available method, including an explosion.

There is a method of collecting oil from under the ice cover of a flowing reservoir, described in the article "Method for the localization and elimination of emergency oil spills at underwater crossings of oil pipelines", published in the journal "Pipeline transport of oil" No. 11 for 1999. The method consists in cutting ice cover across the water stream at an angle to its dynamic axis and establish a barrier in it that directs oil to the coastal zone where the oil receiver is arranged in the form of an open lane. The fence has a rigid structure, large dimensions (6 × 1.5 m) and weight, for its installation special mechanization is required, which is not always possible due to the thickness of the ice. In addition, due to the rigid structure of the barrier, it is impossible to bridge all the gaps between the ice sheet and the barrier, which arise due to the uneven surface of the ice sheet, as a result, part of the oil floats up and freezes in cold air.

Closest to the claimed method is a method of protecting an ice-covered body of water from oil spills using a barrier that is installed in the ice sheet cuts (RF patent No. 2370593, ЕОВВ 15/00). The barrier consists of two elastic shells, the lower shell being filled with water and having a weighting agent, and the upper shell being filled with air under excessive pressure and closes the slot in the ice.

The disadvantages of this technical solution are the great complexity and duration associated with the formation of slots in ice over the entire width of the reservoir, and additional equipment is required to fill the bottom shell with water.

The objective of the present invention is to provide an effective method of installing a boom under the ice of a flowing reservoir for collecting oil products.

To solve this problem, oil is collected from under the ice cover of a flowing reservoir by directing it to an open oil receiver using a boom that is installed through a lane in the ice cover across the water flow at an angle to its dynamic axis. The installation of the boom is carried out by using a pole with a mounting cable, followed by its movement under the ice from one hole to another until the pole reaches the opposite lane.

The proposed method is illustrated by drawings, where in FIG. 1 shows a General view of the implementation of this method; in FIG. 2, section A-A of FIG. 1 with the placement of a boom under ice; in FIG. 3 shows a technology for implementing a method of installing a boom under ice.

The proposed method is as follows. When an oil pipeline breaks downstream, an oil slick spreads under the ice. When installing the fence, the flow rate and the time elapsed since the accident are taken into account. The angle between the boom of the boom installation and the dynamic axis of the water flow depends on the flow velocity. Downstream of the river, at the proposed installation site of the boom, using a chain saw create an oil receiver in the form of an open lane 1, the size of which allows the oil collecting device to be immersed in it. In lane 1 there is also a weighting cable 15 of a boom. On the edge of lane 1 (from the shore), motionless relative to the ice surface, set the drum 2 with a ratchet mechanism and a winding handle of the mounting cable to the drum.

On the opposite bank, upstream, a lane 3 is created with a width that allows placing a weighting cable 15 of a boom in it (when dragging it to lane 1). At the edge of lane 3 (from the shore), a drum 4 with a ratchet mechanism and a winding handle is installed. The drum 4 is fixed motionless. A boom is wound on the drum 4. The boom consists of an elastic shell 13, a skirt 14 and a weighting cable 15. When unwinding the drum 4, a boom is fed to lane 3.

Lines 1 and 3 near the shores of the reservoir are located relative to each other with such a shift so that the line connecting them forms an acute angle with the dynamic axis of the water flow. An acute angle is necessary so that the surface layers of water with oil products are sent to lane 1, where oil products are pumped out of the reservoir using an oil collecting device, i.e. the reservoir is being cleaned.

From lane 1 to lane 3 draw a straight center line 5. Having departed from line 5 1 ÷ 2 m downstream (parallel to it), draw a second line 6. On line 6 with a constant step L = 3 m markup. According to this marking, slots are made in the form of cylindrical holes 7 over the entire thickness of the ice, using, for example, an ice drill with a diameter of 200 mm.

The placement of the cylindrical holes 7 on line 6, parallel to line 5, along which the boom is installed, allows you to reduce the distance of the broach mounting cable 8 from lane 1 to lane 3.

м между линиями 5 и 6 равно величине стрелы прогиба троса-утяжелителя 15 от напора водного потока. Если это расстояние будет меньше стрелы прогиба, то нефть будет попадать в лунки 7.Since line 6 is parallel to line 5, it also forms an acute angle with the dynamic axis of the water flow. Distance

m between lines 5 and 6 is equal to the value of the arrow deflection of the weighting cable 15 from the pressure of the water stream. If this distance is less than the deflection arrow, the oil will fall into wells 7.

The distance L between the holes 7 depends on the length of the pole 9 and 3 m is accepted (with a pole length of 3.5 m), which allows to ensure the exact hit of the pole 9 in the next hole when it is rotated. A longer pole (more than 3.5 m) complicates the process of pulling the mounting cable 8 under the ice from one lane to another, because the water pressure on it increases, its weight increases, and in this case it is difficult to hold a pole 9 with a mounting cable. The pole 9 has a ring in the middle, and at the ends of the handle (these elements are not indicated in the drawings), it has positive buoyancy and low weight, which makes it convenient to control.

The first cylindrical hole 7 from the edge of lane 1 is also located at a distance of 3 m. The mounting cable 8, which is wound on the drum 2, is attached with a carabiner (lock-lock) to the ring of the pole 9. Post 9, with the mounting cable 8 attached to it, lowered into lane 1. Holding the pole 9 by the handle on one of its ends, orient it with respect to the first hole 7 so that the opposite end with the handle of the pole 9 appears in this hole 7. In this case, the drum 2 is rotated using the handle, and the mounting the cable 8 is unwound (ratchet mechanism of the drum in this case Unlock tea).

As soon as the end face of the pole 9 in hole 7 appears, it is turned by hand behind the other end in the direction of the next hole 10, there it is caught and rotated 180 ° in the direction of the next hole 11. Thus, from one hole to the other, the pole 9 with a mounting cable 8 overcomes the entire planned route on line 6 from lane 1 to lane 3, located on the opposite side of the reservoir (river).

In lane 3, a mounting cable 8 is unhooked from a pole 9. Then, a weighting cable 15 of a boom wound around the drum 4 is hooked to the mounting cable 8. On the opposite bank, near lane 1, the handle of the drum 2 is rotated, winding the mounting cable 8 onto drum 2. In this case, the cable 8, using the weighting cable 15, carries a boom into the lane 3, which is dragged further under the ice in the direction of the lane 1. The drum 4 in this case is unlocked, i.e. it rotates freely and the boom with the weighting cable is unwound.

After the boom appears in lane 1, near the drum 2, at a depth of 10 ÷ 20 cm, the weighting cable 15 is pulled by a mounting cable 8 and fixed, while the drum 4 on the opposite bank is fixed, for example, using a ratchet mechanism. Then the mounting cable 8 is disconnected from the weighting cable 15.

When tensioning the weighting cable 15, the elastic sheath 13 and the skirt 14 of the boom are pulled along with it. When moving from one shore to another (from lane 3 to lane 1), the boom boom deviates from line 5 by the flow of water, therefore, it needs to be stretched. The boom should be located on the originally planned line 5, and the holes 7 drilled parallel to it should be downstream, 1-2 meters from the installed boom.

Then, air (compressor unit 12) is supplied to the elastic shell 13 of the boom barrier until it is completely filled. Air, filling the elastic shell 13 of the boom, provides a snug fit of the boom to the lower surface of the ice 16, which prevents oil from entering the boom. Barrier material: synthetic gas-oil-resistant material.

As seen in FIG. 2, the skirt of the fence 14 hangs down (due to the metal weighting cable 15), i.e. straightens, which also prevents the flow of oil in the upper layers of water.

An oil slick, reaching a boom barrier, slides along the elastic shell 13 and skirt 14 and rushes to the shore, in lane 1, with an equipped oil recovery device, from which oil, as it accumulates, is pumped into the tank.

After completion of the spill response, air is discharged from the air elastic shell 13 of the boom. The fixed weighting cable 15 is attached to the mounting cable 8. On the drum 2, the ratchet mechanism is turned off and, turning the handle of the drum 4, the boom is wrapped around the drum 4. The mounting cable 8 is also unwound from the drum 2 and holds the boom in the direction of line 5 , i.e. it does not allow the flow to demolish the boom and provides reliable winding it onto the drum 4. Upon completion of winding, the mounting cable 8 is disconnected from the weighting cable 15 and wound onto the drum 2, i.e. he takes his starting position.

Thus, the task of installing a boom under ice was solved in an effective way, i.e. full cutting of the ice cover of the reservoir is not required to install a boom in this section.

You can use the proposed method in summer conditions, while quick installation and dismantling is carried out, because no holes required. This allows you to quickly respond to the elimination of oil spills in running water.

The boom boom and attachments for its installation are compact and relatively light in weight, they can be transported by any means of transport. The installation method allows to avoid the formation of a deflection ("pocket") in the fence, which ensures the full delivery of oil to the oil receiver. In addition, oil is collected immediately over the entire width of the reservoir (large river, river with high flow rates). All this extends the scope of the proposed method.

In addition, the proposed method is less time-consuming, because allows you to conduct most of the operations not on ice, but on the shore of the reservoir, ensuring safety for workers, and also allows you to not open the ice cover over the entire width of the flowing reservoir, with subsequent extraction of ice fragments from the water, which makes the method.

Thus, the proposed method is simpler, more efficient and safer.

Claims (2)

1. A method of installing a boom barrier under the ice of a flowing reservoir for collecting oil products, including cutting out ice and water lanes in an ice reservoir, installing a weighting cable with a boom in one coastal lane and then pulling the cable at an angle to the dynamic axis of the water flow, characterized in that the slots in the ice are made in the form of cylindrical holes for the entire thickness of the ice and they are placed in one line with a constant step, for example 3 m, and the line for placing the holes is parallel to the line of tension of the cable a boom, while from one coastal lane a pond is brought under the ice to the first hole, a pole with a mounting cable attached to it, directing it to the second hole, in which the pole is rotated 180 °, while the opposite end of the pole is directed to the third hole, and so sequentially from one hole to another until reaching the pole with the mounting cable of the opposite shore lane, then the mounting cable is disconnected from the pole and the weighting cable with a boom is attached to the mounting cable and it is made yazhku under ice toward the lane on the opposite side of the reservoir, then produce its stretch with the mounting of a cable and fixed. 2. The method according to p. 1, characterized in that after tensioning and fixing the weighting cable, air is injected into the elastic shell of the boom.

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